Emad OveisiDr Emad Oveisi is a senior scientist at the Interdisciplinary Centre for Electron Microscopy (CIME), EPFL.
Emad received a BSc in Metallurgy and Materials Engineering (2005) and an MSc in Materials Science (2008) both from the University of Tehran (Iran). He graduated with a PhD in Materials Science and Engineering at EPFL in 2014 for a thesis on the "Three-Dimensional STEM Imaging of Dislocations" under the direction of Prof. Cécile Hébert. The PhD thesis at the Electron Spectrometry and Microscopy Laboratory (LSME), served as an introduction to many of the advanced microscopy techniques that have proven to be a platform for his research career. A post-doctoral research at the centre for electron microscopy gave him the opportunity to peruse a cutting-edge research on one of the most modern aberration-corrected transmission electron microscopes.Since the inauguration of the Energypolis campus of EPFL in Sion, he has been the manager and reference scientist of the electron microscopy platform of EPFL-Valais, working with 9 research groups and more than 200 researchers. In addition to this core responsibility, he provides advanced microscopy consulting and service to EPFL scientists and assist their research to the highest level possible.
Emad Oveisi’s research focuses on the application and development of novel electron microscopy techniques, with emphasis on 3D imaging of crystal defects, as well as the precision measurement of materials properties using aberration-corrected S/TEM. In 2018, he received the prestigious Microscopy Innovation Award for inventing “Single-shot three-dimensional electron imaging”, a novel technique that enables 3D imaging of in situ dynamics.
In 2016 Emad was elected as an interim representative for the scientific staff ("corps intermédiaire") to the Council of the Institute of Chemistry (ISIC). Since 2019, he is a member of EPFL Teachers’ Council (CCE) and has been elected as one of its four bureau members. This role allows him to be exposed to new ideas and pedagogical challenges, as well being involved in discussions with the Vice Presidency of Education (VPE) and other teaching organisations for defining teaching strategies at the EPFL.
Jürg Alexander SchiffmannAfter obtaining his diploma in mechanical engineering from EPFL in 1999 he co-founded a start-up company dedicated to the design of gas bearing supported rotors. In 2005 he joined Fischer Engineering Solutions where he led the development of small-scale, gas bearing supported high-speed turbomachinery for fuel cell air supplies and for domestic scale heat pumps. In parallel he worked on his PhD, which he obtained from EPFL in 2008 and for which he was awarded the SwissElectric Research Award. He then joined the Gas Turbine Lab at MIT as a postdoctoral associate where he worked on foil bearings and on the experimental investigation of radial diffusers. In 2013 he was nominated assistant professor at the Ecole Polytechnique Fédérale de Lausanne where he founds the Laboratory for Applied Mechanical Design. His current research interest are in gas lubricated bearings, in aerodynamics of small-scale compressors and turbines and in automated design and optimization methodologies.
Arnaud LattyTravail de master en acoustique: développement d'une méta-ligne de transmission active
Luc ThévenazDe nationalité suisse et né à Genève, Luc Thévenaz a obtenu en 1982 le diplôme de physicien, mention astrophysique, de l'Université de Genève et le doctorat ès sciences naturelles, mention physique, en 1988 de l'Université de Genève. C'est durant ces années de thèse qu'il a développé son domaine d'excellence, en l'occurrence les fibres optiques et leurs applications. En 1988, Luc Thévenaz a rejoint l'Ecole Polytechnique Fédérale de Lausanne (EPFL), où il dirige actuellement un groupe de recherche en photonique, notamment en optique dans les fibres et dans les capteurs. Ses domaines de recherche couvrent les capteurs à fibre optique basés sur la diffusion Brillouin, l'optique non-linéaire dans les fibres, la lumière lente et rapide et la spectroscopie laser dans les gaz. Ses réalisations principales sont: - l'invention d'une configuration innovante pour les capteurs répartis Brillouin, basée sur l'emploi d'une seule source laser, ce qui lui donne une grande stabilité intrinsèque et qui a permis de réaliser les premières mesures hors laboratoire avec ce type de capteur; - le développement d'un capteur de gaz à l'état de traces, basé sur une détection photoacoustique et utilisant une source laser à semi-conducteur dans le proche infra-rouge, pouvant détecter une concentration du gaz au niveau du ppb; - la première démonstration expérimentale de lumière lente et rapide dans les fibres optiques qui puissent être contrôlées par un autre faisceau lumineux, réalisées à température ambiante et fonctionnant à n'importe quelle longueur d'onde grâce à l'exploitation de la diffusion Brillouin. La première vitesse de groupe négative dans les fibres a aussi été démontrée selon le même principe. En 1991, il a visité l'Université PUC de Rio de Janeiro au Brésil, où il a travaillé sur la génération d'impulsions picoseconde avec des diodes laser. En 1991-1992 il a travaillé à l'Université de Stanford aux USA, où il a participé au développement d'un gyroscope basé sur un laser Brillouin à fibre. Il a rejoint en 1998 l'entreprise Orbisphere Laboratories SA à Neuchâtel en Suisse en tant qu'expert scientifique, avec pour tâche de développer des capteurs de gaz à l'état de traces, basés sur la spectroscopie laser photoacoustique. En 1998 and 1999 il a visité le Korea Advanced Institute of Science and Technology (KAIST) à Daejon en Corée du Sud, où il a travaillé sur des capteurs de courant électrique utilisant un laser à fibre optique. En 2000 il a été un des co-fondateurs de l'entreprise Omnisens SA à Morges en Suisse, qui développe et commercialise de l'instrumentation et des capteurs optiques de pointe. En 2007 il a visité l'Université de Tel Aviv, où il a étudié le contrôle tout-optique de la polarisation de la lumière dans les fibres optiques. Durant l'hiver 2010, il a séjourné à l'Université de Sydney en Australie (CUDOS: Centre for Ultrahigh bandwidth Devices for Optical Systems) où il a étudié les apllications de la diffusion Brillouin stimulée dans les guides d'onde à base de verres chalcogénures. En 2014, il a séjourné à L'Université Polytechnique de Valence en Espagne, où il a travaillé sur les applications photoniques pour les micro-ondes exploitant la diffusion Brillouin stimulée. Il a été membre du Consortium formé pour le projet européen FP7 GOSPEL "Gouverner la vitesse de la lumière", a été Président de l'Action Européenne COST 299 "FIDES: Les fibres optiques pour relever les nouveaux défis de la société de l'information" et est auteur ou co-auteur de quelques 480 publications et 12 brevets. Il est actuellement Coordinateur du projet H2020 Marie Skłodowska-Curie Innovative Training Networks FINESSE (FIbre NErve Systems for Sensing). Il est co-Editeur-en-Chef de la revue "Nature Light: Science & Applications" et Membre du Comité Editorial (Editeur Associé) de la revues suivantes: "APL Photonics" et "Laser & Photonics Reviews". Il a été élevé au rang de "Fellow" par l'IEEE, ainsi que par la Société Optique (OSA).
Berend SmitBerend Smit received an MSc in Chemical Engineering in 1987 and an MSc in Physics both from the Technical University in Delft (the Netherlands). He received in 1990 cum laude PhD in Chemistry from Utrecht University (the Netherlands). He was a (senior) Research Physicists at Shell Research from 1988-1997, Professor of Computational Chemistry at the University of Amsterdam (the Netherlands) 1997-2007.
In 2004 Berend Smit was elected Director of the European Center of Atomic and Molecular Computations (CECAM) Lyon France. Since 2007 he is Professor of Chemical Engineering and Chemistry at U.C. Berkeley and Faculty Chemist at Materials Sciences Division, Lawrence Berkeley National Laboratory. Since 2014 he has been director of the Energy Center at EPFL.
Nava SetterNava Setter completed MSc in Civil Engineering in the Technion (Israel) and PhD in Solid State Science in Penn. State University (USA) (1980). After post-doctoral work at the Universities of Oxford (UK) and Geneva (Switzerland), she joined an R&D institute in Haifa (Israel) where she became the head of the Electronic Ceramics Lab (1988). She began her affiliation with EPFL in 1989 as the Director of the Ceramics Laboratory, becoming Full Professor of Materials Science and Engineering in 1992. She had been Head of the Materials Department in the past and more recently has served as the Director of the Doctoral School for Materials.
Research at the Ceramics Laboratory, which Nava Setter directs, concerns the science and technology of functional ceramics focusing on piezoelectric and related materials: ferroelectrics, dielectrics, pyroelectrics and also ferromagnetics. The work includes fundamental and applied research and covers the various scales from the atoms to the final devices. Emphasis is given to micro- and nano-fabrication technology with ceramics and coupled theoretical and experimental studies of the functioning of ferroelectrics.
Her own research interests include ferroelectrics and piezoelectrics: in particular the effects of interfaces, finite-size and domain-wall phenomena, as well as structure-property relations and the pursuit of new applications. The leading thread in her work over the years has been the demonstration of how basic or fundamental concepts in materials - particularly ferroelectrics - can be utilized in a new way and/or in new types of devices. She has published over 450 scientific and technical papers.
Nava Setter is a Fellow of the Swiss Academy of Technical Sciences, the Institute of Electrical and Electronic Engineers (IEEE), and the World Academy of Ceramics. Among the awards she received are the Swiss-Korea Research Award, the ISIF outstanding achievement award, and the Ferroelectrics-IEEE recognition award. In 2010 her research was recognized by the European Union by the award of an ERC Advanced Investigator Grant. Recently she received the IEEE-UFFC Achievement Award (2011),the W.R. Buessem Award(2011), the Robert S. Sosman Award Lecture (American Ceramics Society) (2013), and the American Vacuum Society Recognition for Excellence in Leadership (2013).
